JP2005510641A - Inflatable insulator including pressure discharge means - Google Patents

Abstract

The present invention is an inflatable module which is breathable, i.e. permits the passage of moisture vapor, and which further incorporates a pressure relief means for reducing pressure in the inflated portion should the module be subjected to sudden or excessive stress. In a preferred embodiment of the invention, a pressure relief valve is incorporated as the pressure relief mechanism in the inflatable module. The present invention is further directed to an inflatable module having increased seal strength to make it capable of withstanding the rigors of use.

Description

  The present invention relates to an inflatable insulator module that is breathable, i.e., allows water vapor transmission. The modules of the present invention can be incorporated into a wide variety of garments such as suits, vests, jackets, trousers, hats, socks, and boots. This module can also be used for sleeping bags and bed covers. The modules of the present invention allow the wearer to adjust the amount of insulation provided according to the environmental conditions experienced or the activities the wearer is engaged in. The module of the present invention is also provided with a relief valve means for reducing the pressure in the expansion portion even if the module is subjected to sudden or excessive stress. In another aspect, the module of the present invention is provided with a seam assembly with increased strength to enable it to withstand harsh applications.

  Inflatable garments are well known in the art. Also known are air impermeable, water vapor permeable materials that form the inflatable part of the insulation module. GB-A-2,317,102 describes such a module. The air impermeable, water vapor permeable material taught in this publication is an independent elastic material such as polyurethane. This material must be sufficiently elastic to compensate for stresses caused by expansion, bending or impact. In order to have sufficient strength, the material must have a minimum thickness of 50 μm, preferably 100-150. It has been found that the use of relatively thick membranes reduces module breathability. In some embodiments, both sides of the inflatable cavity are formed from such a relatively thick membrane, further reducing breathability.

  GB-A-2,323,015 describes variable insulation with an inflatable layer made from an envelope of breathable material formed from a laminated array of hydrophilic films bonded to a microporous substrate. List the materials. This specification selects a microporous and hydrophilic combination material sold under the trade name GORE-TEX ™ by W.L. Gore & Associates, Inc. The composite article is positioned such that an inflatable cavity is formed by hermetically sealing the hydrophilic material with the microporous substrate outside the hydrophilic film.

The invention described in GB-A-2,323,015 offers many advantages, but especially when subjected to extreme stresses such as impact, the garment tends to leak or rupture. Have. Consider improving these shortcomings of the prior art.
The purpose of the present invention will become clear from the following description.

  The present invention improves upon the invention described in GB-A-2,323,015, as well as other inflatable breathable modules. The wearer (as a result of movement or carelessness) may hit or bump an inanimate object that suddenly applies excessive pressure to the module, tearing the seam forming an inflatable cavity, thereby further removing the module Often disabled. GB-A-2,317,102 attempts to prevent this problem by using a thick, independent elastic film (such an application has been found to reduce the breathability of the module).

  Previously known production methods such as those described in GB-A-2,317,102 are based on high energy welding. Two hermetic breathable films are joined by hermetic sealing or high energy welding, usually with or without an adhesive. In general, these welding methods require continuous contact of the film to ensure a hermetic bond and prevent encapsulation of the load bearing structure (fibrous layer) within the seal. In order to increase the integrity of this bond, the film used is relatively thick and suffers from the above disadvantages.

  The seal may be stressed when the inflatable module is inflated or when the object or ground collides with the inflated cavity. Stress may be concentrated at the seal corner or end point. Since stress moves from a weld or bond line to a thin film that cannot transmit stress, resulting in microfractures or tears, microfracture of the expanded cavity often occurs at these stress concentration points. Film resiliency alone does not prevent microfracture, and thin breathable airtight films prevent the module from maintaining an expanded or insulated state due to microfracture of the fabric.

  The present invention provides improved breathability while preventing seam failure.

  In one aspect, the present invention is an inflatable module having one or more inflatable cavities within the module, the module being breathable (ie capable of passing water vapor), And further, it incorporates pressure relief means to reduce the pressure of the expanded portion (s) even if the module is subjected to sudden or excessive stress. In a preferred embodiment of the present invention, a pressure relief valve is incorporated into the inflatable module as a pressure relief mechanism.

  The present invention also relates to an inflatable, breathable module having one or more inflatable cavities within the module, wherein the cavity has a layer of breathable fabric adjacent to the breathable fabric. It is also directed to a breathable module that is formed by sealing and further incorporates means for increasing the strength of the seal, even if the module is subjected to sudden or excessive stress. In a preferred embodiment, the seal allows a continuous bond between the hermetic layers to form a structural bond between the inner reinforced fabric layers that make up the interior of the breathable fabric and the inflatable cavity.

The operation of the present invention will become apparent when considered in conjunction with the accompanying drawings.
Referring to FIG. 1, an embodiment is shown in an inflatable module of the present invention that includes an inflatable insert for a garment such as a jacket or vest. This inflatable insert has a width 1 corresponding to the circumference of the wearer's body when the insert is incorporated into the garment. The sealed periphery 2 represents the periphery of the inflatable cavity 6 formed from a breathable layer. The sealed perimeter 2 can be formed by any suitable sealing technique such as adhesive, heat and pressure, high energy welding, etc., thereby forming a sealed inflatable cavity 6. Inner seal line 7 represents an additional optional seal that can be provided between the breathable fabric layers of the module to form a particular expansion pattern within the expandable cavity 6. The peripheral part 3 is an end part of the inflatable insert 10 and corresponds to an end part of the cut fabric laminate of this insert.

Suitable breathable fabrics that can be incorporated into the present invention are inherently air impermeable and water vapor permeable single layer materials, coated to be air impermeable and water vapor permeable, or Included is a laminate of the material being processed or a material incorporating an air impermeable and water vapor permeable layer. Preferred may be incorporated into the novel construction of the present invention, air impermeable and water vapor permeable fabric, generally large water vapor transmission rate than 2000g / m ^2/24 hours, more preferably, 5000 g / m ² / Has a water vapor transmission rate greater than 24 hours. A particularly preferred laminate for use in the present invention comprises a microporous membrane and an air impermeable and water vapor permeable layer.

  Inflation valve 4 (which can optionally also function as a deflation valve for deflating the cavity) is shown schematically in the figure to reach sealable in inflatable cavity 6. ing. A suitable inflation or inflation / deflation valve can be incorporated into the module of the present invention to allow for the best inflation to the desired degree of inflation, and for example, opening the valve allows the best to deflate To do. A typical inflation valve incorporated in such an inflatable module can be a valve that can be inflated using a mouth, thereby blowing air into the inflatable cavity 6 by the wearer. In this aspect, the inflation valve 4 is oriented at a location near the wearer's mouth so that the wearer is wearing the insert and is easily accessible for inflation.

  Also schematically shown in FIG. 1 is a pressure relief valve 5 that is directed to extend sealably into an inflatable cavity. This pressure relief valve 5 can be placed in any desired position of the inflatable cavity.

  Referring to FIG. 2, there is shown a detailed cross-sectional view of one preferred pressure relief valve that can be incorporated into the inflatable module of the present invention. The pressure relief valve 20 includes a poppet 22 and a spring 24 thereon. As previously described with respect to FIG. 1, the pressure relief valve 20 is incorporated into an inflatable module so that the valve reaches the inflatable cavity 6 as shown. In the embodiment shown in FIG. 2, the relief valve is pressed into the tube 26, and this tube is bonded to the fabric laminate 29 with an adhesive 28.

  This pressure relief valve is subject to, for example, sudden or excessive pressure on this module, movement or carelessness, or hitting or bumping inanimate objects when a relatively constant high pressure (psi) is applied to the valve When high pressure is applied, the spring is compressed and air is expelled from the inflatable cavity by the relief valve assembly. However, it will be apparent to those skilled in the art that this pressure relief valve construction is not the only suitable construction adapted for use in the present invention. Furthermore, depending on the structure of the module, various inflatable cavities can be placed in the module, and in each inflatable cavity, inflating means and Pressure relief means can be provided.

  The pressure relief provided by the pressure relief valve can vary depending on the expansion limit of the inflatable cavity, the strength of the seam of the sealed inflatable module, the expected burst stress imposed on the module, and the like. In a preferred embodiment, the pressure relief value, or “crack” value (ie, the pressure at which the pressure relief valve operates) is in the range of about 0.2-3 psi, more preferably in the range of about 0.4-1.5 psi. Selected within.

  An inflatable module is provided, for example, in FIG. 1, wherein the sealed periphery 2 is formed to provide a single inflatable cavity, or optionally multiple inflatable cavities. can do. "Inflatable cavity" or "inflatable module" means an air sac formed in a cavity that can maintain a pressure different from its surroundings by sealing together an air impermeable fabric layer To do. In one aspect, the sealed perimeter 2 includes a unique seal assembly that forms a hermetic bond between at least two breathable fabric layers, thereby forming an inflatable cavity that is sealed. “Seal” in one aspect means a bond between at least two fabric layers.

  The seal assembly of the present invention includes at least two fabric layers joined together with an adhesive. In a preferred embodiment, the seal assembly (FIG. 3) includes two breathable fabric layers, each including an air impermeable, water vapor permeable layer 34 and an internal reinforcing fabric layer 30. The seal assembly further includes an adhesive that penetrates the two reinforced fabric layers and contacts adjacent air impermeable layers to form the seal 40. Preferably, the fibers of the inner reinforcing fabric layer form a structural seal that is fully penetrated and encapsulated by the adhesive. Seals are provided for both optionally sealed peripheral and internal seal lines.

  “Reinforced woven layer” means a fibrous layer such as a woven, knitted or non-woven material. Preferred reinforced fabric layers of the present invention are sufficiently open so that a seal can be formed therethrough. Examples of suitable fibrous sheets include, but are not limited to, lightweight knitted fabrics, open nonwoven fabrics, open woven fabrics, and multifilament and monofilament knitted fabrics, including at least one of nylon, polyester, polypropylene, cotton, and the like.

  Suitable breathable fabrics incorporated into the present invention are materials that are inherently air impermeable and water vapor permeable and have a reinforced fabric layer. When sealing two breathable fabrics together, an internal reinforcing fabric layer from the two breathable fabrics is placed opposite each other to form the interior of the inflatable cavity.

  Preferred air impermeable, water vapor permeable materials include, but are not limited to, polyurethane and composites of polyurethane and PTFE. Preferred polyurethane layers or those used as composites with other materials have a thickness of 0.005 inches or less, most preferably 0.003 inches or less; more preferred polyurethanes are 0.002 or less, And it has a thickness of 0.0015 or less. Polyurethanes having a thickness of 0.0005 or less are also suitable for use in the present invention. Preferably, an air impermeable, water vapor permeable material is laminated or coated on at least one side of the reinforced fabric layer to form a breathable fabric layer. Preferred breathable fabric layers include PTFE / polyurethane composites laminated to knitted or non-woven fibrous sheets, polyurethane laminated to knitted or non-woven fabrics, particularly preferred are stretch expanded PTFE / polyurethane composites. is there.

  Adhesives suitable for use in the present invention include, but are not limited to, polyurethanes including reactive polyurethanes and thermoplastic polyurethanes, silicones, PVC, and the like.

  An adhesive is provided between the inner reinforcing fabric layers of the breathable fabric to be joined. Methods for providing an adhesive to the internally reinforced fabric layer include bead extrusion, printing, and the like. The adhesive flows with heat and pressure between the inner reinforced fabric layer of one breathable fabric and the reinforced fabric layer of the second breathable fabric to form a seal. The internal reinforcing fabric layers of the first and second breathable fabric layers are encapsulated in the applied adhesive to join the two breathable fabric layers. “Encapsulated” means that the adhesive flows around the fibers of the fabric layer and enters the weave to fill the material. In the most preferred embodiment, the adhesive is a reactive adhesive that flows through a heated platen press. Adhesive penetrates the first and second reinforcing fabric layers and contacts adjacent air impermeable layers.

  Encapsulation in the range of inflatable cavities in both adjacent reinforced fabric layers diffuses stress from the air impermeable film to the load bearing internal reinforced fabric layer, making the module stress free without compromising air opacity. Or make it more suitable to withstand stress concentration. Surprisingly, it has been found that inflatable bodies incorporating a reinforced fabric layer in the seal assembly can withstand stress and are resistant to failure at internal and peripheral seals. Surprisingly, an inflatable module having a thin hermetic film but incorporating a reinforced fabric layer in the seal assembly is stronger than a module without a reinforced fabric layer or a welded module (FIG. 6) and within the hermetic film. It was found to be more resistant to micro breakage (FIG. 4). FIG. 4 represents microfracture resulting from stress in a module formed by welding and sealing two polyurethane layers together without a reinforced inner fabric layer. It has been found that the use of an internally reinforced fabric layer in the preferred inflatable module of the present invention improves the seal strength of failure to 50%, more preferably more than 100%, even more preferably 500% or more (internally reinforced fabric layer). Compared to the seal strength between two breathable fabric layers without a).

  Additional layers can be included in the inflatable modules of the present invention. In a particularly preferred embodiment (36 in FIG. 3), the inflatable module includes an outer layer of a breathable fabric layer, such as an outer shell layer. This can be beneficial if there is likely to be a lot of wear and puncture. In a further aspect, the inflatable module includes a breathable insulator, and a portion of the breathable insulator can be held in place by an adhesive.

  Based on the teachings of the prior art, a unique combination of breathable inflatable modules further incorporating pressure relief means to protect the module against undesired leakage or rupture when subjected to sudden excessive external pressure Benefits that were not realized are provided. In addition, a breathable inflatable module is provided that incorporates a unique seal assembly that protects the module from stress concentrations that cause seal failure and microfracture of thin fabric layers. The pressure relief means and the seal assembly can be used together or separately to provide protection against stress due to service conditions.

Without intending to limit the scope of the present invention, the following examples illustrate how to make and use the present invention.
Example 1
The inflatable module of the present invention was assembled as follows.
An inflatable vest or insert was made by first cutting two fabric panels having a configuration substantially as shown in FIG. Each fabric panel comprises a polyester knit shell layer, an air impermeable, water vapor permeable polyurethane layer microporous expanded PTFE membrane on the membrane opposite the shell layer, and an internal polyester knitted layer. A polyurethane adhesive bead pattern substantially corresponding to the pattern of the peripheral seal 2 and seal line 7 of FIG. 1 is applied to the inner knitted fabric layer and the adhesive penetrates through the inner polyester knitted layer. Sufficient pressure and heat were applied so that each laminate was brought into contact with the air impermeable and water vapor permeable layer to form an airtight seal.

  A dough tube was created near the shoulder region of the insert to reach the inflatable cavity of the insert, as indicated by reference numeral 4 in FIG. The dough tube was made by applying parallel adhesive bead wires that seal the laminate together into a tubular structure. A silicone tube was then inserted into the fabric tube and bonded to form an airtight seal between the two tubes. Then, a plastic expansion valve (Oral Matic Valve 730 ROA, Halkey Roberts, Inc., St. Petersburg, FL) was pushed into the silicone tube to produce an airtight seal.

As indicated by reference numeral 5 in FIG. 1, a dough tube was created near the lower corner area of the insert to reach the inflatable cavity of the insert to insert a pressure relief valve. The dough tube was made by applying parallel adhesive bead wires that seal the laminate together into a tubular structure. A silicone tube was then inserted into the fabric tube and bonded to form an airtight seal between the two tubes. A pressure relief valve (Oral Relief Valve 730 ROARO55, Halkey Roberts, Inc., St. Petersburg, FL) with a pressure relief of 0.55 psi was pushed into the silicone tube to produce an airtight seal.
The resulting inflatable module was incorporated as a lining insert in the jacket shell.

Example 2
The three layer PTFE laminate was sealed with an adhesive bead along with the inner fibrous layer. The inflatable module of the present invention was assembled as follows.

An inflatable vest or insert was made by cutting two fabric panels having a configuration substantially as shown in FIG. Each fabric panel (prepared according to FIG. 3) has an outer fabric layer 36, a breathable fabric layer 34, and an internal reinforcement layer 30. One fabric panel consists of a 90 g / m ² polyester round knitted shell layer 36, a 30 μm thick micropore with a 15 μm thick air impermeable, water vapor permeable polyurethane layer on the membrane opposite the shell layer. It comprises a laminate of a textured expanded PTFE membrane 34 and a 30 g / m ² internal polyester warp knitted layer 30. The second fabric panel consists of a 30 g / m ² polyester warp knitted shell layer 36, a 15 μm thick air impermeable, water vapor permeable polyurethane layer 15 μm thick on the membrane opposite the shell layer. It comprises a laminate of a porous expanded PTFE membrane 34 and a 30 g / m ² internal polyester warp knitted layer 30. Reactive polyurethane adhesive 40 was applied with a bead pattern substantially corresponding to the pattern of peripheral seal 2 and internal seal line 7 of FIG. This adhesive was applied between the inner knitted fabric layers (about 1 g / m). Apply sufficient pressure (0.2 bar) and heat (125 ° C.) to allow the adhesive to penetrate and encapsulate through this inner polyester knitted layer, and each laminate as seen in the scanning photomicrograph of FIG. An air tight seal was formed by continuous contact with the body's air impermeable, water vapor permeable layer. The adhesive was then cured for at least 48 hours, after which seam strength or expansion was measured. The results of seal strength can be seen in Table 1 below.

Example 3
The bilayer PTFE laminate was sealed using an adhesive bead without an inner fibrous layer. The sample was assembled as follows.
50 g / m ² nylon warp knitted layer, 30 μm thick microporous expanded PTFE membrane with a 15 μm thick air impermeable, water vapor permeable polyurethane layer on the membrane opposite the warp knitted layer A dough panel comprising a laminate of was laid flat. The thermoplastic polyurethane was melted and an adhesive bead was applied to both the machine and transverse directions on the opposite side of the knitted layer using a pneumatic hot glue gun. This adhesive was applied at about 1 g / m. Immediately, the second fabric panel was placed on top of the first panel with the applied adhesive. The second layer is a 50 g / m ² nylon warp knitted layer, a 30 μm thick microporous layer having a 15 μm thick air impervious, water vapor permeable polyurethane layer on the membrane opposite the warp knitted layer. It comprises a laminate of textured expanded PTFE membrane. The knitted layer of the second panel was brought together from the first fabric panel. After laying the second panel, while the adhesive is still in a flowable (melted) state, a steel bar 6 inches long and 3 inches in diameter is forcefully rotated over the sample to approximately 17 bar. Pressure was applied.

  The applied adhesive was continuously brought into contact with the air impermeable and moisture permeable layers of each laminate to form an airtight seal without a fibrous layer on the inside. The adhesive was cooled and then the seal strength was measured. The results of the seal strength can be seen in Table 1.

Example 4
The PTFE laminate was sealed with an adhesive bead along with the inner fibrous layer. The sample was assembled as follows.
A laminate of a 50 g / m ² nylon warp knitted layer, a 30 μm thick microporous expanded PTFE membrane having a 15 μm thick air impermeable, water vapor permeable polyurethane layer to which the knitted layer is bonded. The resulting dough panel was laid flat on a table. The thermoplastic polyurethane was melted and an adhesive bead was applied to both the machine and transverse directions on the side of the knitted layer using a pneumatic hot glue gun. This adhesive was applied at about 1 g / m. Immediately, the second fabric panel was placed on top of the first panel and the adhesive was applied. The second layer is a 50 g / m ² nylon warp knitted layer, a 30 μm thick microporous expanded PTFE membrane having a 15 μm thick air impermeable and water vapor permeable polyurethane layer to which the knitted layer is applied. It comprises a laminate. The knitted layer of the second panel was aligned from the first fabric panel toward the knitted layer. After laying the second panel, while the adhesive is still in a flowable (melted) state, a steel bar 6 inches long and 3 inches in diameter is forcefully rotated over the sample to approximately 17 bar. Pressure was applied.

  The applied adhesive penetrated both knitted layers and continuously contacted the air impermeable, moisture permeable layer of each laminate to form an airtight seal with a fibrous layer inside. . The adhesive was cooled and then the seal strength was measured. The results of the seal strength can be seen in Table 1.

Example 5
The two-layer polyurethane laminate was sealed using an adhesive bead without an inner fibrous layer. The sample was assembled as follows.
A fabric panel comprising a laminate of a 60 g / m ² polyester warp shell layer and a 25 μm thick air impermeable, water vapor permeable polyurethane film (Estane 1710) supplied by Narcoate, LLC is laid flat. It was. The thermoplastic polyurethane was melted and an adhesive bead was applied to both the machine and transverse directions on the opposite side of the knitted layer using a pneumatic hot glue gun. This adhesive was applied at about 1 g / m. Immediately, the second fabric panel was placed on top of the first panel with the applied adhesive. The second layer comprises a laminate of a 60 g / m ² polyester warp shell layer and a 25 μm thick air impermeable, water vapor permeable polyurethane film (Estane 1710) supplied by Narcoate, LLC. The knitted layer of the second panel was brought together from the first fabric panel. After laying the second panel, while the adhesive is still in a flowable (melted) state, a steel bar 6 inches long and 3 inches in diameter is forcefully rotated over the sample to approximately 17 bar. Pressure was applied.

  The applied adhesive was continuously brought into contact with the air impermeable and moisture permeable layers of each laminate to form an airtight seal without a fibrous layer on the inside. The applied adhesive in the expandable module was then cooled and then the seal strength was measured. The results of the seal strength can be seen in Table 1.

Example 6
The polyurethane laminate was sealed with an adhesive bead along with the inner fibrous layer. The sample was assembled as follows.
A fabric panel comprising a laminate of a 60 g / m ² polyester warp shell layer and a 25 μm thick air impermeable, water vapor permeable polyurethane film (Estane 1710) supplied by Narcoate, LLC on a table. Lay flat. The thermoplastic polyurethane was melted and an adhesive bead was applied to both the machine and transverse directions on the side of the knitted layer using a pneumatic hot glue gun. This adhesive was applied at about 1 g / m. Immediately, the second fabric panel was placed on top of the first panel and the adhesive was applied. The second layer comprises a laminate of a 60 g / m ² polyester warp shell layer and a 25 μm thick air impermeable, water vapor permeable polyurethane film (Estane 1710) supplied by Narcoate, LLC. The knitted layer of the second panel was aligned from the first fabric panel toward the knitted layer. After laying the second panel, while the adhesive is still in a flowable (melted) state, a steel bar 6 inches long and 3 inches in diameter is forcefully rotated over the sample to approximately 17 bar. Pressure was applied.

  The applied adhesive penetrated both knitted layers and continuously contacted the air impermeable, moisture permeable layer of each laminate to form an airtight seal with a fibrous layer inside. . The applied adhesive in the expandable module was then cooled and then the seal strength was measured. The results of the seal strength can be seen in Table 1.

Example 7
The three layer PTFE laminate was sealed with an adhesive bead along with the nonwoven inner fibrous layer. The inflatable module of the present invention was assembled to be substantially consistent with Example 2 except that a different fabric was used. An inflatable vest or insert was made by cutting two fabric panels having a configuration substantially as shown in FIG. One fabric panel consists of a 60 g / m ² polyester braided shell layer, a 15 μm thick air impervious, water vapor permeable polyurethane layer 15 μm thick on the membrane opposite the shell layer. It comprises a laminate of a porous stretched expanded PTFE membrane and a 25 g / m ² point bonded internal nonwoven layer. The second fabric panel is a 30 μm thick microporous material having a 25 g / m ² point bonded internal nonwoven layer, a 15 μm thick air impermeable, water vapor permeable polyurethane layer on the membrane opposite the shell layer. A laminate of an expanded PTFE membrane and a 25 g / m ² point bonded inner nonwoven layer. The nonwoven fabric of the first fabric panel was aligned with the nonwoven fabric adhered to the polyurethane layer of the second panel.

  The applied adhesive penetrated both nonwoven layers and continuously contacted the air impermeable, moisture permeable layer of each laminate to form an airtight seal with a fibrous layer inside. . The applied adhesive was allowed to cure for at least 48 hours, after which the seal strength was measured. The results of the seal strength can be seen in Table 1.

Test method Water vapor transmission rate (MVTR)
To measure MVTR, approximately 70 ml of a solution consisting of 35 parts by weight potassium acetate and 15 parts by weight distilled water was placed at the mouth into a 133 ml polypropylene cup with an inner diameter of 6.5 cm. Minimum MVTR of approximately expanded polytetrafluoroethylene (PTFE) membrane having a 85,000g / m ^2/24 hours, heated sealed at the edge of the cup, without leakage solution taut containing the microporous partition wall Formed.

  A similar expanded PTFE membrane was attached to the surface of the aquarium. This water tank assembly was controlled at 23 ° C. + 0.2 ° C. using a temperature-controlled room and a water circulation tank.

  Test samples were conditioned at room temperature 23 ° C. and 50% relative humidity, after which the test procedure was performed. The sample was placed so that the microporous polymer membrane was in contact with the expanded polytetrafluoroethylene membrane attached to the surface of the aquarium and allowed to equilibrate for at least 15 minutes before being introduced into the cup.

  The cup assembly was weighed to almost 1/1000 g and placed upside down on the center of the test sample.

  Water movement is provided by a driving force between the water in the aquarium and a saturated salt solution that provides a water flux by diffusion in that direction. The sample was tested for 15 minutes, after which the cup assembly was removed and again weighed in the 1/1000 g range.

The MVTR of the sample was calculated from the weight gain of the cup assembly, per 24 hours, expressed in grams of water per sample area m ^2.

Seal Strength Test To measure the strength of a seal, specimens were cut from three example inflatable modules in both the machine direction and the transverse direction. The sample was 6 inches long with a seal in the middle. The seal length was 1 inch perpendicular to the tensile axis. The sample was attached to an Instron model # 122 equipped with an air clamp jaw that held the sample film. The crosshead was extended at a speed of 20 inches / minute until the sample broke. The load at break and the elongation to break were recorded. Averages in both machine direction and cross direction are averaged and reported in Table 1.

  While particular embodiments of the present invention have been illustrated and described herein, the present invention should not be limited to such figures and descriptions. Obviously, modifications and improvements may be implemented and embodied as part of the present invention within the scope of the following claims.

FIG. 1 is a schematic diagram of an inflatable module of the present invention that includes an inflatable insulating jacket, or vest insert, that incorporates a pressure relief assembly. FIG. 2 is a cross-sectional view of a pressure relief valve assembly suitable for use with the present invention. FIG. 3 is a schematic view of the seal assembly of the present invention. FIG. 4 is a scanning photomicrograph of micro-breaks in the high energy welded polyurethane laminate. FIG. 5 is a scanning micrograph of a cross section of a three-layer PTFE laminate having a seal according to one embodiment of the present invention. FIG. 6 is a scanning photomicrograph of a cross section of the welded polyurethane material.

Claims (22)

At least two fabric layers, each fabric layer comprising an air impermeable, water vapor permeable layer, these layers being sealed together by a seal between the layers to form an inflatable cavity;
An inflatable module comprising means for inflating the inflatable cavity incorporated in the module,
An inflatable module further comprising means for allowing the inflatable cavity to relieve pressure when the cavity is inflated and subjected to an extreme stress exceeding a predetermined amount.   The inflatable module of claim 1, wherein the at least two fabric layers comprise a fabric having an air impermeable, water vapor permeable coating thereon.   2. An inflatable module according to claim 1, wherein said pressure relief means is a pressure relief valve.   The inflatable module of claim 1, wherein said means for inflating also functions to release pressure for contraction of the module.   The inflatable module of claim 1, wherein each of said cavities comprises a plurality of said inflatable cavities incorporating an inflating means and a pressure releasing means. Said at least two fabric layers, inflatable module of claim 1 comprising a laminate having a large water vapor permeability than 5000 g / m ^2/24 hours.   The inflatable module of claim 3, wherein the pressure relief valve relieves pressure when the module is subjected to extreme stress to produce an internal pressure within the inflatable cavity of 0.4 psi or greater.   The inflatable module of claim 3, wherein the pressure relief valve relieves pressure when the module is subjected to extreme stress to produce an internal pressure in the inflatable cavity of 1.5 psi or greater.   The at least two fabric layers include at least two laminates, each laminate including an air impermeable, water vapor permeable layer, and the laminate is configured to form an inflatable cavity. An inflatable module according to any one of the preceding claims, which is sealed together by a seal between the permeable, water vapor permeable layers.   The at least two laminates include a microporous membrane and an air impermeable, water vapor permeable layer, and the laminate is a seal between the air impermeable and water vapor permeable layers to form an inflatable cavity. An inflatable module according to any one of the preceding claims, sealed together by.   Wherein said at least two fabric layers sealed together by a seal to form an inflatable cavity comprise an air impermeable, water vapor permeable layer, an adjacent internal reinforcing fabric layer, and an adhesive; Any of the preceding claims, wherein a layer is encapsulated by the adhesive and the air impermeable, water vapor permeable layer is in contact with the adhesive to form a seal between the at least two fabric layers. The inflatable module described.   The inflatable module of claim 11, wherein the at least two fabric layers comprise an internally reinforced fabric layer having an air impermeable, water vapor permeable coating thereon.   The inflatable module of claim 11, wherein the at least two fabric layers are PTEF / polyurethane composites laminated to a reinforced fabric layer.   The inflatable module of claim 11, wherein the reinforced fabric layer is a woven, knitted or non-woven material.   The inflatable module of claim 11, wherein the reinforced fabric layer comprises at least one of polyester, cotton and nylon.   The inflatable module according to any one of the preceding claims, wherein the air impermeable, water vapor permeable layer is a film, knitted fabric or non-woven fabric.   The inflatable module according to any one of the preceding claims, wherein the air impermeable, water vapor permeable layer is polyurethane.   The inflatable module according to any one of the preceding claims, wherein the at least two fabric layers comprise PTEF and polyurethane.   An inflatable module according to any one of the preceding claims, wherein the seal is formed by an adhesive and the adhesive is polyurethane, silicone or PVC polyvinyl chloride.   The inflatable module according to any one of the preceding claims, wherein the adhesive is a reactive polyurethane and a thermoplastic polyurethane.   The inflatable module according to any of the preceding claims, wherein the module comprises a breathable insulating insert in the garment.   21. The inflatable module of claim 20, wherein a portion of the breathable insulating insert is encapsulated with an adhesive.

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